WO2017202676A1 - Automatic optimization of an operating parameter of an electric machine - Google Patents

Abstract

The invention relates to a motor control assembly (30) for an electric machine (34) and to a corresponding method. The motor control assembly (30) has a current-measuring device (32) for determining current values (I), a memory device (36) for storing the current values (I), and a control device (38), wherein the control device is designed to vary a value (A) of the operating parameter in a predefined interval (∆A1), and wherein the motor control assembly (30) is designed to store associated current values (I) in the memory device (36). A minimum current value (I0) is then determined on the basis of the stored current values (I).

Description

description

Automatic optimization of an operating parameter of an electrical machine

The invention generally relates to the control or activation of electrical machines. In particular, the invention relates to a motor drive arrangement for an electrical machine and to a corresponding method.

Electrical machines are used in various variants in many areas of industry, in particular in the automotive industry. A widely used variant is in ^¬ example the electronically commutated motor, also known as EC synchronous motor (EC), which permanent magnets for driving and used for example in fuel pumps and / or water pumps, inter alia, in motor vehicles of any kind and beyond becomes .

Such electrical machines can be operated in various electrical operating modes and / or by means of various motor controls or motor drives. One type of motor control is, for example, the so-called block commutation, in which individual phases of the electrical machine are energized during operation.

A sub-form of the motor control is also the sensorless control, in which by means of a voltage induced in the stator coils of the motor during a blanking interval a

Determined position of the rotor and thus the indexing of the rotating field can be precisely controlled.

For actual operation operating here are often set parameters of the engine and corresponding values of the operation ^¬ parameters to adjust the motor control.

For example, a drive regime (also Pulse) se-width modulation called drive frequency), ie a frequency with which the voltage is clocked during individual Kommutierungsblöcke be set. It is also possible, for example, to set a control angle, ie an angle between the beginning of an electrical activation or an energization of a phase and an actual mechanical rotor position.

In principle, values of the operating parameters can be left at a constant value and the motor can thus be operated. In most cases, however, a characteristic curve and / or a characteristic diagram is generated and stored, for example, in a control unit, such a characteristic field typically being designed for safe operation.

Characteristics defined in such characteristic curves and / or characteristic diagrams are interpolated by mathematical methods during the operation of electrical machines, in particular in the case of fuel pumps, in order to obtain further values of the operating parameters for a current operating condition, such as e.g. a current load and / or speed to determine and to control the engine accordingly.

It is an object of the present invention to provide a method and a motor control arrangement for an electrical machine, by means of which the electric machine can be optimally controlled and / or operated individually and taking into account current operating conditions. This object is solved by the subject matter of the independent claims. Further advantageous embodiments will be apparent from the dependent claims.

According to one aspect of the invention, a motor control ^¬ arrangement is proposed for an electrical machine. The motor control arrangement has a current measuring device for determining, determining, measuring and / or detecting a current value of an electric machine assigned during operation. passed electric current. Furthermore, the motor control arrangement has a memory device for storing current values determined by the current measuring device and a regulating device for adapting and / or varying at least one value of at least one operating parameter

electrical machine on. The control device is set up to vary a value of the operating parameter, in particular a current value, in a predetermined and / or predetermined interval during operation of the electrical machine. The motor control arrangement and / or the current mes seinrichtung is adapted to be deposited with variation of the value of the operating parameter through the current measurement means ermit ^¬ Telte current values in the memory device. The motor control arrangement and / or the control device is further adapted to determine based on the determined at variation of the value of the operating parameter and stored in the SpeI ^¬ chervorrichtung current values a minimum current value.

In other words, according to the invention, at least one value of at least one operating parameter is varied during operation of the electric machine, and the current values corresponding to the varied values are stored in the memory device. It is also possible to vary several values of different operating parameters simultaneously or one after the other. Also, each varied or associated with the current values of the operating parameter values can be stored in the SpeI ^¬ chervorrichtung to obtain information on the current supplied to the electric machine as a function of the respective operating parameter. This information can be about the distribution of the current values as a function of the values of the operating parameter, in particular as data in the memory device ^¬ be present. On the basis of these current values and / or values of the operating parameter, the minimum current value can thus be determined. The electric machine can in particular designate an electrically commutated motor (EC synchronous motor), as can be used in particular in fuel pumps or water pumps. However, the electric machine may also designate any other type of electric machine.

The current measuring device may be part of the electrical machine or be present as a separate measuring device, which may be connected to the electric machine.

The memory device can be any type of memory, in particular a random access memory (RAM) and / or a random access memory

FLASH memory, his. The predetermined and / or predefined interval may designate an arbitrary value range of the operating parameter by a current value of the operating parameter with which the electrical is driven. For example, the interval can be between 5% and 50% of the current value.

Another aspect of the invention relates to a vehicle having an electric machine and a motor control assembly as described above and below. The vehicle is, for example, a motor vehicle, such as a car, bus or truck, or even a rail vehicle, a ship, an aircraft, such as a helicopter or airplane, or, for example, an electrically operated bicycle.

Yet another aspect of the invention relates to a method for determining an optimum value of an operating parameter for an electrical machine.

Features, elements and / or properties of the Motorsteue ^¬ approximately arrangement and / or of the vehicle can be and vice versa features, elements and / or properties of the process. According to one embodiment of the invention, the engine control arrangement is further configured to determine an optimum value of the operating parameter associated with the minimum current value. The optimum value may designate an optimum operating point and / or operating point for the respective operating condition of the electrical machine, for example a respective load and / or rotational speed. In other words, the optimum value may correspond to that value of the operating parameter for which a power consumption of the electric machine is minimal under the current operating conditions. The optimum value can also be stored in the storage device for the respective operating condition at which it was determined (eg load, rotational speed).

According to one embodiment of the invention, the engine control arrangement is further adapted to adjust a current value of the operating parameter of the electric machine according to the optimum value. In other words, the machine can be operated with the determined optimal value. So the electric machine can be supplied with a minimum

electrical power or under supply of a minimum amount of electricity are ideally operated, and it can be saved power to operate the electrical machine.

The invention can be considered to be based in particular as to the below ^¬ be written thoughts and insights. As described above, static characteristic maps and / or characteristic curves for engine control are currently used, with interpolation points of the characteristic curves being adapted to adapt values of operating parameters to the respective operating conditions and thus to operate the electric machine. Frequently, the individual support points for individual copies of the electrical machine and under selected conditions are measured and stored for all subsequently produced copies of the electric machine. Thus, in particular individual manufacturing differences, such as tolerances, for copies of the electric machines of a series in the Motor control disregarded. In real operation, the conditions for the respective electrical machine used in a vehicle, for example, may differ from the conditions to which the characteristic data refer. Under certain circumstances, the electric machine can not be operated in an optimum working range. A non-optimal operation or work area can in this case designate a control of the machine in which electrical energy is applied for the operation of the machine, which, however, is not converted into a torque. In this case, any form of power loss can be generated.

On the other hand, by determining the optimum values of operating parameters, a working range of the electric machine, in particular of a fuel pump, can be extended and a power loss can be reduced. Also, the electric machine can be operated more gently at the optimum value because, for example, mechanical loads such as vibrations can be reduced or avoided if a current value of the operating parameter, i. a parameterization, changed and / or adapted. As an example, a lower drive frequency paired with a minimum turn-on time will cause a small current area, i. Power can produce in a motor, whereby a lower speed can be achieved. Furthermore, for example, a variation of the field angle can lead to a more stable, in particular quieter or vibration-poor, running of the motor.

According to one embodiment of the invention, the operating parameter is at least one element selected from the list comprising a drive angle, a drive regime, a switching time, a field angle, a block width and as external operating parameters, for example the operating voltage, the medium temperature, the actual pressure and the viscosity the liquid. By determining optimal values for the various operating parameters, such a running behavior of the electrical machine can be further improved in an advantageous manner become. In particular, power consumption can be further reduced. The respective optimum values of different operating parameters can be determined simultaneously or sequentially one after the other.

According to one embodiment of the invention, the motor control arrangement is further configured to perform a mathematical evaluation of the current values as a function of the values of the operating parameter based on the current values stored in the memory device. A mathematical evaluation can include, for example, the determination of a derivative, the determination of a trend and / or any other evaluation, such as a fit. The trend can be determined, for example, by interpolation of measured values, variation calculation, averaging and / or any other mathematical methods.

According to one embodiment of the invention, the motor control arrangement is further configured to determine a trend (40) of the current values (I) as a function of the values (A) of the operating parameter and based on the current values (I) stored in the memory device (36) the ermit ^¬ telten trend (40) an optimum value (Z) to determine the operating parameter. In other words, can be determined and / or in accordance with current Betriebsbedin ^¬ conditions based on the determined trend of the optimum value can be calculated. The trend is determined can provide a clue as to whether a further iteration a new or actual optimum value should be determined game, iteratively at ^¬.

According to one embodiment of the invention, the control device is further adapted to vary the value of the Betriebspa ^¬ rameters of the electrical machine in a further interval. The further interval can be the same size, larger or smaller than the original interval. This can be particularly advantageous if the optimum value is not in the original interval, but outside. In this way, the optimum value can be determined by iterative adaptation and / or shifting of the interval or an interval size.

According to one embodiment of the invention, the control device is further configured to stochastically the value of ^¬ Betriebspa rameters, linear, exponential, logarithmic and / or vary according to a polynomial function within the interval. Any other mathematical methods can also be used to vary the value of the operating parameter.

According to a further aspect of the invention, a method for determining an optimum value of an operating parameter for an electrical machine is specified. The method comprises the steps of varying, in particular by means of a Regelvor ^¬ direction, a value of the operating parameter of the electric machine in a predetermined interval. In particular, the value of the operating parameter can be varied by a current value. In a further step, current values of a current supplied to the electric machine during operation are determined, for example by means of a current measuring device. The current values can be determined during the variation of the values of the operating parameter. In a further step, the current values are stored and / or stored in a memory device. The current values can, as a function of the (varying) values of Be ^¬ operating parameters in the memory device are stored in ^¬ play. In a further step an optimum value of the operation ^¬ parameters is determined based on the stored current values and / or determined.

According to an embodiment of the invention, the step of determining the optimum value further comprises the step of determining a minimum current value from the stored current values. Alternatively or additionally, the step of determining the optimum value comprises the step of determining a trend of Current values as a function of the values of the operating parameter, which were previously varied.

The subject matter of the invention will be explained below with reference to figures, without the subject matter of the invention being limited thereby.

FIG. 1 a schematically shows a current consumption of an electrical machine as a function of a control angle.

FIG. 1b schematically shows a characteristic curve for

 an electric machine.

FIG. 1c schematically shows a current consumption of an electrical machine as a function of a drive angle.

Figure 2a schematically shows an engine control ^¬ arrangement according to an embodiment of the invention.

FIGS. 2b to 2f each show a current consumption as

 Function of a control angle.

FIGS. 3a to 3f each show a current consumption as

 Function of a control angle.

FIG. 4 shows a vehicle with a motor control arrangement according to an embodiment of the invention.

FIG. 5 shows a flow chart for illustrating steps of a method according to an embodiment of the invention. Identical and / or equivalent features and elements are provided in the figures with the same reference numerals.

1 a schematically shows a current consumption or a current I supplied to an electric machine 34 during operation as a function of a drive angle A of an electric machine 34 (see FIGS. 2 a and 4). FIG. 1 b schematically shows a characteristic curve for an electrical machine 34 and FIG. 1 c 1 a shows schematically the current consumption or the current I as a function of the drive angle A. FIGS. 1 a, 1 b, 1 c serve to illustrate thoughts and findings underlying the invention.

For clarity, the current will micrograph below, the current supplied and current values provided with the reference numbers I ^¬ Be. Similarly, the drive angle and values of the drive angle with the reference sign A is provided.

The drive angle A denotes an angle between the start of an electrical drive or a current supply of a phase of the electric machine 34 and an actual mechanical rotor position. Current consumption I and drive angle A are shown in arbitrary units. In Figure lb, a characteristic curve for an electric machine 34 is shown schematically, wherein the drive angle A is shown as a function of the speed in any units. The characteristic curve in this case represents a one-dimensional map having different Ansteu ^¬ erwinkeln A to the rotational speed F. Individual points of the characteristic curve correspond to different operating points, wherein an operating point can be a specific value of the actuation angle A at a specific rotational speed.

Shown in FIG. 1a is a first curve 10 and a second curve 12 of the current I as a function of the drive angle A, the curves 10, 12 respectively corresponding to constant mechanical operating parameters. Curve 10 may be, for example, operation of a fuel pump at 5000 rpm and pressure For example, curve 12 may correspond to operation at 8000 rpm and 4 bar.

On the basis of the characteristic curve from FIG. 1b, a value of the drive angle A is determined for currently used electrical machines 34, for example read out from a control unit or determined by means of interpolation of stored characteristic data according to FIG. The value of the driving angle A thus determined is then supplied to the electric machine 34 for control. This is also called the electrical machine 34.

In the example shown in FIGS. 1a, for example, an operating point 13 for the curve 12 and an operating point 11 for the curve 10 can be determined so that the electric machine 34 is operated with the values A for the actuation angle associated with the respective operating points 11, 13 can. The operating points 11, 13 can thus denote a pair of values (I, A) each of a current value I and a drive angle A. The actual operating points 11, 13 of the electric machine 34 do not coincide with the respective optimum operating points 14, 16 corresponding optimum values of the drive angle A, in which the current consumption I for the respective curve 10, 12 is minimal. Obviously, the work point 13 associated value of the drive angle for the curve 12 is too high and the operating point 11 associated value A for the curve 10 is too low. For both cases, therefore, by changing the drive angle A, an energetic advantage, i. a Stromersparnis be achieved, which is characterized in Figure la with ΔΙιο for curve 10 and with ΔΙ12 for curve 12. Depending on the operating condition, this advantage can be greater or smaller.

In general, therefore, the current consumption I of the electrical machine 34 can be influenced by changing the electrical control angle A or associated values A, wherein in the examples shown in FIGS. 1a and 1b different drive angles, ie angle of the magnetic field to the rotor, and thus different power ratios electrical Energy can not be optimally converted into mechanical energy under all conditions, ie at different speeds and / or loads. The mechanical energy is in each case constant for the curves 10, 12, which can also be referred to as characteristic curves, so that along each curve 10, 12 there is an optimum value for the activation angle A corresponding to the respective operating condition. At different loads and different rotational speeds, the optimum values of the phase control for the optimum working points 14 may, however, vary for 16 different electric machines 34 from each other, which may be due for example to manufacturing technology Un ^¬ differences and / or manufacturing tolerances. So far, this behavior has only been taken into account in static form, for example by means of static characteristics, as shown in FIG. 1b, which in some cases can not cover all conditions. As an approximation, this fact is improved in current electrical machines 34 on the basis of a complex characteristic diagram. For example, often become two-dimensional

Characteristic curves stored in a control unit. In this case, for example, for different loads, for example, different pressures for an electric pump, one of the curves shown in Figure lb corresponding characteristic can be stored. As a rule, however, further operating parameters which may influence the behavior of the electric machine 34, such as, for example, an operating voltage or a fluid temperature in a fuel pump, are not taken into account in the case of two-dimensional and / or multi-dimensional maps. For simple applications, however, an improvement can already be achieved with a two-dimensional map. For more complex applications, however, this improvement is often unsatisfactory. When using a complex load system, such as a demand-variable variable-pressure fuel system, loads on the engine, such as a fuel pump, may be introduced be very different in different operating conditions. The motor or the pump is therefore, with high probability, rarely operated with the respective optimum value corresponding to this operating condition, ie, the value of the drive angle A assigned to the respective optimum operating point 14, 16.

The dash-dotted line 18 in FIG. 1 a shows by way of example the expected course of the optimum value of the drive angle for different operating conditions. Different Betriebsbe ^¬ conditions may, for example, different speeds and / or different loads of the electric machine 34, ie, for example, different pressures for an electric pump, be.

The aim of the present invention is therefore to operate the electric machine 34 under all operating conditions with the respective optimum operating point 14, 16 associated value of the Ansteu ^¬ Angled A. The two hatched areas 20, 22 can be limiting. Region 22 is in some form an overload, ie the mechanical energy generated from the electrical energy may not be sufficient in this region 22 to safely rotate the electric machine 34. When engine is mapped by means of characteristic diagrams, as shown in FIG. 1b, this region 22 is generally avoided for worst-case engines, and a considerable distance from the actual one may occur

Represent borderline. In contrast, the electric machine 34 is pulled in the area 20 with a lot of force, although this would not be necessary. Mechanically, this is expressed, for example, in

Vibrations of the electric machine, which experiences the rotor or the load.

By way of example, the behavior of an electric machine 34 in the regions 20, 22 in FIG. 1c for the curve 10 of FIG. 1a is shown. FIG. 1c shows, analogously to FIG. 1a, the current consumption I as a function of the driving angle A. In FIG. 1c, it can be seen that strong variances in the current consumption I can occur in the regions 20, 22, which are respectively identified as "min, max" in the regions 20, 22. On the basis of these variances, it can be recognized, for example, that the electric current Machine 34 in one of the border areas 20, 22 works, which should be avoided.

FIG. 2a schematically shows a motor control arrangement 30 according to an embodiment of the invention. Figures 2b to 2f schematically illustrate an operation of the Motorsteue 2a ^¬ approximately assembly 30 of FIG. The diagrams in FIGS. 2b to 2f show the current consumption I as a function of the drive angle A and are shown in arbitrary units.

The motor control arrangement 30 has a current measuring device 32 for determining a current value or current values I of an electric current I supplied to an electric machine 34 during operation. Furthermore, the motor control arrangement 30 has a memory device 36 for storing current values I determined by the current measuring device 32 and a control device 38 for adapting and / or varying at least one value of at least one operating parameter of the electric machine 34. The operating parameter is exemplified below, as illustrated in detail with reference to the figures 2b to 2f, a drive angle A. The operating parameter may alternatively or additionally, for example, a Ansteuertreguenz, a field angle, a block width and / or a switching time. The electric machine 34, which may for example be a motor and / or a pump, is set by the Motorsteue ^¬ approximately arrangement 30 with a firing angle X in operation, that is made to run, or is already running. The An ^{¬ control} angle X can be determined, for example, based on a characteristic, as shown in Figure lb. The control device 38 now varies a value of the Ansteu ^¬ Angled A in a predetermined interval ΔΑ1, for example in a range of values Xa to X + a. The value of the drive angle A can be varied stochastically, linearly, exponentially, logarithmically and / or according to a polynomial function within the interval ΔΑ1. When the value of the drive angle A is varied, the current measuring device 32 determines current values I which are stored in the memory device 36 by the motor control arrangement 30 and / or the current measuring device 32.

The current values I determined by varying the drive angle A within the interval ΔΑ1 from X-a to X + a are shown schematically in FIG. 2b as a function of the values of the drive angle A. Based on these current values I, a minimum current value Ii is now determined by the motor control arrangement 30.

For this purpose, based on the measured values of FIG. 2b, a trend 40 of the current values I is determined as a function of the values A of the drive angle, as shown by way of example in FIG. 2c. The trend 40 can be any approximation function of the measured values, ie the value pairs (I, A), from FIG. 2b. In other words, the measured values of FIG. 2 b are evaluated by the motor control arrangement 30, from which the trend 40 can result. The trend 40 shown in Figure 2c is a monotonically increasing function of the current I as a function of the phase control A, which an indication can be sure that the value Xa does not speak of the phase control A at the current value Ii to the value of the minimum current consumption ent ^¬ and thus not yet the ideal operating point for the electric machine 32 is found. The value of lowest power consumption can therefore be at smaller values of A Ansteu ^¬ erwinkels as Xa.

Thus, the drive angle is varied approximately in a further iteration or a further iteration loop in a further interval ΔΑ2 from Xb to X + b by the value Xa. For this variation, the above applies with respect to the variation in Interval ΔΑ1 said, ie in particular, the variation stochastic, linear, exponential, logarithmic and / or carried out according to a polynomial function. This process can also take place several times, gradually iteratively or randomly until by the determined distribution of the current values I and a mathematical evaluation of the optimum working range is ^¬ represents has or until a minimum current value 10 at an op ^¬ timalwert Z of the phase control A found is as shown in Figure 2e. This point Z is now maintained as an optimal operating point 14, which can also be stored in the storage device 36 for a later operation of the electric machine 34, for example based on the value pair (10, Z). Thus, the operating point 14 can be approached directly under similar operating ^¬ conditions. It is also possible to adapt a characteristic curve based on the optimum operating point 14.

In general, the optimum value Z can be determined based on the trend 40 and / or based on the measured values of the current or current values I shown in FIG. 2b and FIG.

Based on the example described above, however, it may be that the optimum operating point 14 lies in a non-safe area 22, as explained in FIG. 1a. This area 22 is defined by the fact that the electric machine 32 is getting too little power to operate safely. Therefore, the optimization described above would run until the electric machine 34 stops. In order to prevent this, it is advisable to take into account further parameters, such as a variance of the current values I.

This limitation is illustrated schematically in FIG. 2f. The variance of the current I is rather low in the normal operating range, however, the current fluctuations can be relatively large under high load or too high and / or too low control angle values. Also, it may happen that another observed operating parameters here more varied than usual, eg the speed can be out of round due to the heavy load and the resulting "heavy running" and therefore have pronounced fluctuations.Here it is important to prevent the optimization in this area 22 running therefore a limitation of optimization may be required.

For example, a threshold for the variance may be stored in the memory device 32, and upon reaching this threshold, the optimization may be stopped. The variance may e.g. be determined by means of a standard deviation.

At this point, it should be noted that in the example described above, the speed can be specified and the current is adjusted accordingly to an optimum. However, it is also possible to choose another form of drive, e.g. a current-controlled operation, in which a current is allowed and sets the maximum possible speed (so-called DC shunt machine). The invention therefore also encompasses embodiments in which the operating parameter current I can be predetermined and values of the rotational speed are recorded until the operating parameter is optimally selected approximately at a maximum rotational speed. Accordingly, the optimum value Z may be a minimum or a maximum.

Figures 3a to 3f show, respectively, a current I as a function of a phase control A and schematically illustrate a functi ^¬ onsweise a motor control assembly 30 according to an embodiment of the invention. Shown is a trend 40, which can be determined as described above.

On the basis of such trends 40, a decision can be made by the motor control arrangement 30 according to the invention, whether a further iteration for determining the optimum operating point 14 and / or the optimum value Z is required or not. Thus, the monotonically increasing trend 40 of Figure 3a indicates that the optimal operating point 14 is at lower values A, whereas it may be found at higher values in the monotonically decreasing trend 40 of Figure 3e. Trend 40 of Figure 3d has a minimum so that the operating point 14 is already found and the iteration can be stopped. In contrast, the trend 40 in FIG. 3 c has a maximum, so that either a further iteration can be advantageous for smaller and / or larger values of the drive angle A, or an optimum operating point 14 corresponding to the maximum can already be found. In the case of the constant trend 40 of FIG. 3b and the zigzag course of the trend 40 in FIG. 3f, it can be assumed, for example, that there is a fault and the optimization should be stopped.

A falling trend 40 may further determine the direction of optimization. A consistent and / or non-uniform trend 40 can be treated differently depending on the technical application. Optionally, a variance may be too low here. Overall, it can thus be decided whether a further iteration is required, while the protection or limit value observation, as illustrated in FIG. 2f, can always be active. In this way it can be prevented that unsafe areas 20, 22 are approached. An advantage here may be that this method can automatically reach an optimum operating point 14 and the arithmetic / regulatory effort can be relatively low. Furthermore, no large, memory-intensive maps need to be maintained. Alternatively or in addition to the trends 40, another mathematical consideration and / or evaluation, e.g. a derivative of any degree, be used.

FIG. 4 shows a vehicle 50 with a motor control arrangement 30 and an electric machine 34 according to an embodiment of the invention. The engine control assembly 30 of FIG. 4 has In doing so, elements and features resemble the most recently described engine control assembly 30.

FIG. 5 shows a flowchart for illustrating steps of a method for determining an optimum value Z of a

Operating parameters according to an embodiment of the invention.

In a first step S1, a value of the operating parameter of the electric machine 34 is varied within a predetermined interval ΔΑ1 and in a step S2 current values I of a current supplied to the electric machine 34 during operation are determined, which are stored in a storage device 32 in a step S3 , In a further step S4, an optimum value Z of the operating parameter is determined on the basis of the stored current values I. Step S4 may include a step of determining a minimum current value 10 from the back ^¬ terlegten current values I and / or of determining a trend 40 of the current values I as a function of the values of A Betriebspa ^¬ rameters.

Claims

A motor control arrangement (30) for an electrical machine (34), comprising: a current measuring device (32) for determining a current value (I) of an electric current supplied to the electric machine during operation; a memory device (36) for storing current values (I) determined by the current measuring device (32); a control device (38) for adjusting at least one value (A) at least one operating parameter of the electric machine (34), wherein the control device (38) is adapted to a value (A) of the operating Para ^¬ meters at a predetermined interval (ΔΑ1) to vary; wherein the motor control arrangement (30) is set up to store current values (I) determined by the current measuring device (32) in the storage device (36) when the value (A) of the operating parameter is varied; and wherein the motor control arrangement (30) is set up to determine a minimum current value (10) based on the current values (I) stored in the memory device (36).

Motor control arrangement (30) according to claim 1,

wherein the engine control assembly (30) is further adapted to determine an optimum value (Z) of the operating parameter associated with the minimum current value (10); and / or wherein the engine control arrangement (30) is further adapted to adapt a current value (A) of the operating parameter of the electric machine (34) in accordance with the optimum value (Z).

The motor control assembly (30) of any one of the preceding claims, wherein the operating parameter is at least one selected from the list comprising a drive angle, a drive regime, a switching time, a field angle, and a block width. Motor control arrangement (30) according to one of the preceding claims, wherein the motor control arrangement (30) is further set up, based on the current values (I) stored in the memory device (36), a mathematical evaluation of the current values (I) as a function of the values (A). of the operating parameter.

Motor control arrangement (30) according to one of the preceding claims, wherein the motor control arrangement (30) is further set up, based on the current values (I) stored in the storage device (36), a trend (40) of the current values (I) as a function of the values ( A) of the operating parameter to determine and based on the determined trend (40) an optimum value (Z) of the operating parameter.

Motor control arrangement (30) according to one of the preceding claims, wherein the control device (38) is further adapted to vary the value (A) of the operating parameter of the electric machine (32) in a further interval (ΔΑ2).

Motor control arrangement (30) according to one of the preceding claims, wherein the control device (38) is further adapted to vary the value (A) of the operating parameter stochastically, linearly, exponentially, logarithmically and / or according to a polynomial function within the interval (ΔΑ1).

Vehicle (50), comprising:

an electrical machine (34); and

An engine control assembly (30) according to any one of claims 1 to 7.

Method for determining an optimum value (Z) of an operating parameter for an electrical machine (34), the method comprising the steps: Varying a value (A) of the operating parameter of the electric machine at a predetermined interval

(ΔΑ1); Determining current values (I) of a current supplied to the electrical machine (34) during operation;

 Deposit the current values (I) in a storage device

(36); and determining an optimum value (Z) of the loading ^¬ operating parameters based on the stored current values ^¬ (I). The method of claim 9, wherein the step of determining the optimum value (Z) further comprises: determining a minimum current value (10) from the stored current values (I); and / or determining a trend (40) of the current values (I) as a function of the values (A) of the operating parameter.